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Burke Minsley

Burke Minsley is a Research Geophysicist with the Geology, Geophysics, and Geochemistry Science Center.

Burke Minsley joined the USGS in 2008 as a Research Geophysicist with the Geology, Geophysics, and Geochemistry Science Center in Denver, Colorado. After receiving a B.S. in Applied Physics from Purdue University in 1997, Burke began his career as a field geophysicist working on offshore seismic vessels before receiving a Ph.D. in Geophysics from MIT in 2007. His work involves the development and implementation of innovative ground-based and airborne geophysical methods used in interdisciplinary studies to improve our understanding of Earth's geosphere, hydrosphere, and cryosphere. Burke's projects are interdisciplinary and geographically diverse, including permafrost mapping in Alaska, critical zone studies in a mountain headwater system in Colorado, and a large regional water availability study in the lower Mississippi River valley. He also works on development of computational methods for uncertainty quantification in geophysical datasets and associated geologic or hydrologic interpretations. In 2012, Burke received the PECASE award for his fundamental research on advancing airborne electromagnetic survey methodology and its use in studying permafrost. He is currently serving as President of the Near-Surface Geophysics Section of AGU from 2021-2022.

Professional Experience

  • 2008 - present: Research geophysicist, Geology, Geophysics, and Geochemistry Science Center, U.S. Geological Survey, Denver, CO

  • 2007 - 2008: Postdoctoral research fellow, Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA

  • 2002 - 2007: Research assistant, Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA

  • 1997 - 2002: Field geophysicist with WesternGeco, offshore

Education and Certifications

  • Ph.D. Geophysics, Massachusetts Institute of Technology, 2007

  • B.S. Applied Physics, Purdue University, 1997

Affiliations and Memberships*

  • American Geophysical Union: President of the Near-Surface Geophysics Section of AGU from 2021-2022

Honors and Awards

  • USGS Unit Award for Excellence of Service - LandCarbon team member, 2017

  • Presidential Early Career Award for Science and Engineering (PECASE), 2012

  • USGS Superior Service Award, 2012

  • Paper one of 'Ten Best of SAGEEP' 2010, 2011

  • Outstanding Student Paper Award, Near Surface section, Fall AGU, 2006

  • Martin Family Society Fellowship for Sustainability, MIT, 2004 - 2005

Science and Products

scientists collecting permafrost cores

Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Warming and thawing of permafrost soils in the Arctic is expected to become widespread over the coming decades. Permafrost thaw changes ecosystem structure and function, affects resource availability for wildlife and society, and decreases ground stability which affects human infrastructure. Since permafrost soils contain about half of the global soil carbon (C) pool, the magnitude of C losses...
By
Ecosystems Land Change Science Program, Geology, Minerals, Energy, and Geophysics Science Center
Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Warming and thawing of permafrost soils in the Arctic is expected to become widespread over the coming decades. Permafrost thaw changes ecosystem structure and function, affects resource availability for wildlife and society, and decreases ground stability which affects human infrastructure. Since permafrost soils contain about half of the global soil carbon (C) pool, the magnitude of C losses...
Learn More
Example of thawing landscapes and thermokarst at our field sites

Arctic Boreal Vulnerability Experiment (ABoVE)

ABoVE: Vulnerability of inland waters and the aquatic carbon cycle to changing permafrost and climate across boreal northwestern North America. Carbon released from thawing permafrost may fuel terrestrial and aquatic ecosystems or contribute to greenhouse gas emission, leading to a potential warming feedback and further thaw.
By
Land Management Research Program, Alaska Science Center
Arctic Boreal Vulnerability Experiment (ABoVE)

Arctic Boreal Vulnerability Experiment (ABoVE)

ABoVE: Vulnerability of inland waters and the aquatic carbon cycle to changing permafrost and climate across boreal northwestern North America. Carbon released from thawing permafrost may fuel terrestrial and aquatic ecosystems or contribute to greenhouse gas emission, leading to a potential warming feedback and further thaw.
Learn More
Table Top Mountain and the West Twin Creek catchment

Nome Creek Experimental Watershed

The Nome Creek Experimental Watershed (NCEW) has been the site of multiple studies focused on understanding hydrology, biogeochemistry, and ecosystem changes related to permafrost thaw and fire in the boreal forest.
By
Land Management Research Program, Alaska Science Center
Nome Creek Experimental Watershed

Nome Creek Experimental Watershed

The Nome Creek Experimental Watershed (NCEW) has been the site of multiple studies focused on understanding hydrology, biogeochemistry, and ecosystem changes related to permafrost thaw and fire in the boreal forest.
Learn More
Filter Total Items: 30

Floating and Towed Transient Electromagnetic Surveys used to Characterize Hydrogeology underlying Rivers and Estuaries: March - December 2018 Floating and Towed Transient Electromagnetic Surveys used to Characterize Hydrogeology underlying Rivers and Estuaries: March - December 2018

Surface and water-borne geophysical methods can provide information for the characterization of the subsurface structure of the earth for aquifer investigations. Floating and towed transient electromagnetic (FloaTEM and tTEM) surveys provide resistivity soundings of the subsurface, which can be related to lithology and hydrogeology. In the TEM method, a primary electrical current is...
By
Water Resources Mission Area

Airborne Electromagnetic (AEM) Survey in Southwest and Southeast Areas, Wisconsin, 2022 Airborne Electromagnetic (AEM) Survey in Southwest and Southeast Areas, Wisconsin, 2022

Airborne electromagnetic (AEM) and magnetic survey data were collected during March 2022 over a distance of 2,574.6 line kilometers in southeast and southwest Wisconsin. These data were collected in support of an effort to improve estimates of depth to bedrock through a collaborative project between the U.S. Geological Survey (USGS), Wisconsin Department of Agriculture, Trade, and...
By
Geology, Geophysics, and Geochemistry Science Center

Alaska permafrost characterization: Geophysical and related field data collected in 2021 Alaska permafrost characterization: Geophysical and related field data collected in 2021

Geophysical measurements were collected by the U.S. Geological Survey (USGS) at five sites in Interior Alaska in September 2021 for the purposes of imaging permafrost structure and quantifying variations in subsurface moisture content in relation to thaw features. Electrical resistivity tomography (ERT) measurements were made along transects 110-222 meters (m) in length to quantify...
By
Geology, Geophysics, and Geochemistry Science Center

Surface electrical resistivity tomography, magnetic, and gravity surveys in Redwell Basin and the greater East River watershed near Crested Butte, Colorado, 2017 Surface electrical resistivity tomography, magnetic, and gravity surveys in Redwell Basin and the greater East River watershed near Crested Butte, Colorado, 2017

Surface electrical resistivity tomography (ERT), time-domain electromagnetics (TEM), nuclear magnetic resonance (NMR), magnetics, and gravity data were acquired in 2016, 2017 and 2018 in the greater East River Watershed near Crested Butte Colorado with a focused effort in Redwell Basin. Five ERT profiles were acquired within Redwell Basin and Brush Creek to map geologic structure at...
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Historical (1940–2006) and recent (2019–20) aquifer slug test datasets used to model transmissivity and hydraulic conductivity of the Mississippi River Valley alluvial aquifer from recent (2018–20) airborne electromagnetic (AEM) survey d Historical (1940–2006) and recent (2019–20) aquifer slug test datasets used to model transmissivity and hydraulic conductivity of the Mississippi River Valley alluvial aquifer from recent (2018–20) airborne electromagnetic (AEM) survey d

The Mississippi River Valley alluvial aquifer (“alluvial aquifer”) is one of the most extensively developed aquifers in the United States. The alluvial aquifer is present at the land surface in parts of southeastern Missouri, northeastern Louisiana, western Mississippi, western Tennessee and Kentucky near the Mississippi River, and throughout eastern Arkansas. Historical (1940–2006) and...
By
Oklahoma-Texas Water Science Center

Airborne electromagnetic and magnetic survey data, northeast Wisconsin (ver. 1.1, June 2022) Airborne electromagnetic and magnetic survey data, northeast Wisconsin (ver. 1.1, June 2022)

Airborne electromagnetic (AEM) and magnetic survey data were collected during January and February 2021 over a distance of 3,170 line kilometers in northeast Wisconsin. These data were collected in support of an effort to improve estimates of depth to bedrock through a collaborative project between the U.S. Geological Survey (USGS), Wisconsin Department of Agriculture, Trade, and...
By
Geology, Geophysics, and Geochemistry Science Center
No results found.
Filter Total Items: 73

Rapid and gradual permafrost thaw: A tale of two sites Rapid and gradual permafrost thaw: A tale of two sites

Warming temperatures and increasing disturbance by wildfire and extreme weather events is driving permafrost change across northern latitudes. The state of permafrost varies widely in space and time, depending on landscape, climate, hydrologic, and ecological factors. Despite its importance, few approaches commonly measure and monitor the changes in deep (>1 m) permafrost conditions with...
Authors
Burke J. Minsley, Neal Pastick, Stephanie R. James, Dana R.N. Brown, Bruce K. Wylie, Mason A. Kass, Vladimir E. Romanovsky
By
Earth Resources Observation and Science (EROS) Center , Geology, Geophysics, and Geochemistry Science Center

GSPy: A new toolbox and data standard for Geophysical Datasets GSPy: A new toolbox and data standard for Geophysical Datasets

The diversity of geophysical methods and datatypes, as well as the isolated nature of various specialties (e.g., electromagnetic, seismic, potential fields) leads to a profusion of separate data file formats and documentation conventions. This can hinder cooperation and reduce the impact of datasets researchers have invested in heavily to collect and prepare. An open, portable, and well...
Authors
Stephanie R. James, Nathan Leon Foks, Burke J. Minsley
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

Bedrock property quantification is critical for predicting the hydrological response of watersheds to climate disturbances. Estimating bedrock hydraulic properties over watershed scales is inherently difficult, particularly in fracture-dominated regions. Our analysis tests the covariability of above- and belowground features on a watershed scale, by linking borehole geophysical data...
Authors
Sebastian Uhlemann, Baptiste Dafflon, Haruko Murakami Wainwright, Kenneth Hurst Williams, Burke J. Minsley, Katrina D. Zamudio, Bradley Carr, Nicola Falco, Craig Ulrich, Susan S. Hubbard
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Mapped predictions of manganese and arsenic in an alluvial aquifer using boosted regression trees Mapped predictions of manganese and arsenic in an alluvial aquifer using boosted regression trees

Manganese (Mn) concentrations and the probability of arsenic (As) exceeding the drinking-water standard of 10 μg/L were predicted in the Mississippi River Valley alluvial aquifer (MRVA) using boosted regression trees (BRT). BRT, a type of ensemble-tree machine-learning model, were created using predictor variables that affect Mn and As distribution in groundwater. These variables...
Authors
Katherine J. Knierim, James A. Kingsbury, Kenneth Belitz, Paul E. Stackelberg, Burke J. Minsley, James R. Rigby
By
Water Resources Mission Area, New England Water Science Center, Lower Mississippi-Gulf Water Science Center, Geology, Geophysics, and Geochemistry Science Center

Characterizing methane emission hotspots from thawing permafrost Characterizing methane emission hotspots from thawing permafrost

Methane (CH4) emissions from climate-sensitive ecosystems within the northern permafrost region represent a potentially large but highly uncertain source, with current estimates spanning a factor of seven (11–75 Tg CH4 yr−1). Accelerating permafrost thaw threatens significant increases in pan-Arctic CH4 emissions, amplifying the permafrost carbon feedback. We used airborne imaging...
Authors
Clayton D. Elder, David R. Thompson, Andrew K Thorpe, Hrishikesh Chandanpurkar, Philip J Hanke, Nicholas Hasson, Stephanie R. James, Burke J. Minsley, Neal J. Pastick, David Olefeldt, Katey M Walter Anthony, Charles E. Miller
By
Earth Resources Observation and Science (EROS) Center , Geology, Geophysics, and Geochemistry Science Center

Permafrost characterization and feature identification using public domain airborne electromagnetic data, interior Alaska Permafrost characterization and feature identification using public domain airborne electromagnetic data, interior Alaska

The Alaska Division of Geological & Geophysical Surveys (DGGS) airborne electromagnetic (AEM) data are an excellent resource for permafrost characterization. AEM data can be used for pingo identification, estimating permafrost thickness, estimating surface talik thickness, evaluating permafrost health (temperature), talik identification and more. Data examples are shown from...
Authors
Abraham M. Emond, Ronald Daanen, Burke J. Minsley
By
Geology, Geophysics, and Geochemistry Science Center

Non-USGS Publications**

Minsley, B., D. Coles, Y. Vichabian, and F.D. Morgan (2008), Minimization of self-potential survey mis-ties acquired with multiple reference locations, Geophysics, 73(2), F71-F81, doi:10.1190/1.2829390.
Minsley, B. (2007), Modeling and inversion of self-potential data, Ph.D. Thesis, Massachusetts Institute of Technology, Cambridge, Massachusetts, 251 p.
Ajo-Franklin, J.B., B.J. Minsley, and T.M. Daley (2007), Applying compactness constraints to seismic traveltime tomography, Geophysics, 72(4), R67-R75, doi:10.1190/1.2742496.
Minsley, B., J. Sogade, and F.D. Morgan (2007), 3D source inversion of self-potential data, Journal of Geophysical Research, 112, B02202, doi:10.1029/2006JB004262.
Minsley, B., J. Sogade, and F.D. Morgan (2007), Three dimensional self potential inversion for subsurface DNAPL contaminant detection at the Savannah River Site, South Carolina, Water Resources Research, 43(4), W04429, doi:10.1029/2005WR003996.
Willis, M.E., D.R. Burns, R. Rao, B. Minsley, M.N. Toksöz, and L. Vetri (2006), Spatial orientation and distribution of reservoir fractures from scattered sesimic energy, Geophysics, 71(5), 43-51, doi:10.1190/1.2235977.

**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.

Science and Products

scientists collecting permafrost cores

Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Warming and thawing of permafrost soils in the Arctic is expected to become widespread over the coming decades. Permafrost thaw changes ecosystem structure and function, affects resource availability for wildlife and society, and decreases ground stability which affects human infrastructure. Since permafrost soils contain about half of the global soil carbon (C) pool, the magnitude of C losses...
By
Ecosystems Land Change Science Program, Geology, Minerals, Energy, and Geophysics Science Center
Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Arctic Biogeochemical Response to Permafrost Thaw (ABRUPT)

Warming and thawing of permafrost soils in the Arctic is expected to become widespread over the coming decades. Permafrost thaw changes ecosystem structure and function, affects resource availability for wildlife and society, and decreases ground stability which affects human infrastructure. Since permafrost soils contain about half of the global soil carbon (C) pool, the magnitude of C losses...
Learn More
Example of thawing landscapes and thermokarst at our field sites

Arctic Boreal Vulnerability Experiment (ABoVE)

ABoVE: Vulnerability of inland waters and the aquatic carbon cycle to changing permafrost and climate across boreal northwestern North America. Carbon released from thawing permafrost may fuel terrestrial and aquatic ecosystems or contribute to greenhouse gas emission, leading to a potential warming feedback and further thaw.
By
Land Management Research Program, Alaska Science Center
Arctic Boreal Vulnerability Experiment (ABoVE)

Arctic Boreal Vulnerability Experiment (ABoVE)

ABoVE: Vulnerability of inland waters and the aquatic carbon cycle to changing permafrost and climate across boreal northwestern North America. Carbon released from thawing permafrost may fuel terrestrial and aquatic ecosystems or contribute to greenhouse gas emission, leading to a potential warming feedback and further thaw.
Learn More
Table Top Mountain and the West Twin Creek catchment

Nome Creek Experimental Watershed

The Nome Creek Experimental Watershed (NCEW) has been the site of multiple studies focused on understanding hydrology, biogeochemistry, and ecosystem changes related to permafrost thaw and fire in the boreal forest.
By
Land Management Research Program, Alaska Science Center
Nome Creek Experimental Watershed

Nome Creek Experimental Watershed

The Nome Creek Experimental Watershed (NCEW) has been the site of multiple studies focused on understanding hydrology, biogeochemistry, and ecosystem changes related to permafrost thaw and fire in the boreal forest.
Learn More
Filter Total Items: 30

Floating and Towed Transient Electromagnetic Surveys used to Characterize Hydrogeology underlying Rivers and Estuaries: March - December 2018 Floating and Towed Transient Electromagnetic Surveys used to Characterize Hydrogeology underlying Rivers and Estuaries: March - December 2018

Surface and water-borne geophysical methods can provide information for the characterization of the subsurface structure of the earth for aquifer investigations. Floating and towed transient electromagnetic (FloaTEM and tTEM) surveys provide resistivity soundings of the subsurface, which can be related to lithology and hydrogeology. In the TEM method, a primary electrical current is...
By
Water Resources Mission Area

Airborne Electromagnetic (AEM) Survey in Southwest and Southeast Areas, Wisconsin, 2022 Airborne Electromagnetic (AEM) Survey in Southwest and Southeast Areas, Wisconsin, 2022

Airborne electromagnetic (AEM) and magnetic survey data were collected during March 2022 over a distance of 2,574.6 line kilometers in southeast and southwest Wisconsin. These data were collected in support of an effort to improve estimates of depth to bedrock through a collaborative project between the U.S. Geological Survey (USGS), Wisconsin Department of Agriculture, Trade, and...
By
Geology, Geophysics, and Geochemistry Science Center

Alaska permafrost characterization: Geophysical and related field data collected in 2021 Alaska permafrost characterization: Geophysical and related field data collected in 2021

Geophysical measurements were collected by the U.S. Geological Survey (USGS) at five sites in Interior Alaska in September 2021 for the purposes of imaging permafrost structure and quantifying variations in subsurface moisture content in relation to thaw features. Electrical resistivity tomography (ERT) measurements were made along transects 110-222 meters (m) in length to quantify...
By
Geology, Geophysics, and Geochemistry Science Center

Surface electrical resistivity tomography, magnetic, and gravity surveys in Redwell Basin and the greater East River watershed near Crested Butte, Colorado, 2017 Surface electrical resistivity tomography, magnetic, and gravity surveys in Redwell Basin and the greater East River watershed near Crested Butte, Colorado, 2017

Surface electrical resistivity tomography (ERT), time-domain electromagnetics (TEM), nuclear magnetic resonance (NMR), magnetics, and gravity data were acquired in 2016, 2017 and 2018 in the greater East River Watershed near Crested Butte Colorado with a focused effort in Redwell Basin. Five ERT profiles were acquired within Redwell Basin and Brush Creek to map geologic structure at...
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Historical (1940–2006) and recent (2019–20) aquifer slug test datasets used to model transmissivity and hydraulic conductivity of the Mississippi River Valley alluvial aquifer from recent (2018–20) airborne electromagnetic (AEM) survey d Historical (1940–2006) and recent (2019–20) aquifer slug test datasets used to model transmissivity and hydraulic conductivity of the Mississippi River Valley alluvial aquifer from recent (2018–20) airborne electromagnetic (AEM) survey d

The Mississippi River Valley alluvial aquifer (“alluvial aquifer”) is one of the most extensively developed aquifers in the United States. The alluvial aquifer is present at the land surface in parts of southeastern Missouri, northeastern Louisiana, western Mississippi, western Tennessee and Kentucky near the Mississippi River, and throughout eastern Arkansas. Historical (1940–2006) and...
By
Oklahoma-Texas Water Science Center

Airborne electromagnetic and magnetic survey data, northeast Wisconsin (ver. 1.1, June 2022) Airborne electromagnetic and magnetic survey data, northeast Wisconsin (ver. 1.1, June 2022)

Airborne electromagnetic (AEM) and magnetic survey data were collected during January and February 2021 over a distance of 3,170 line kilometers in northeast Wisconsin. These data were collected in support of an effort to improve estimates of depth to bedrock through a collaborative project between the U.S. Geological Survey (USGS), Wisconsin Department of Agriculture, Trade, and...
By
Geology, Geophysics, and Geochemistry Science Center
No results found.
Filter Total Items: 73

Rapid and gradual permafrost thaw: A tale of two sites Rapid and gradual permafrost thaw: A tale of two sites

Warming temperatures and increasing disturbance by wildfire and extreme weather events is driving permafrost change across northern latitudes. The state of permafrost varies widely in space and time, depending on landscape, climate, hydrologic, and ecological factors. Despite its importance, few approaches commonly measure and monitor the changes in deep (>1 m) permafrost conditions with...
Authors
Burke J. Minsley, Neal Pastick, Stephanie R. James, Dana R.N. Brown, Bruce K. Wylie, Mason A. Kass, Vladimir E. Romanovsky
By
Earth Resources Observation and Science (EROS) Center , Geology, Geophysics, and Geochemistry Science Center

GSPy: A new toolbox and data standard for Geophysical Datasets GSPy: A new toolbox and data standard for Geophysical Datasets

The diversity of geophysical methods and datatypes, as well as the isolated nature of various specialties (e.g., electromagnetic, seismic, potential fields) leads to a profusion of separate data file formats and documentation conventions. This can hinder cooperation and reduce the impact of datasets researchers have invested in heavily to collect and prepare. An open, portable, and well...
Authors
Stephanie R. James, Nathan Leon Foks, Burke J. Minsley
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

Bedrock property quantification is critical for predicting the hydrological response of watersheds to climate disturbances. Estimating bedrock hydraulic properties over watershed scales is inherently difficult, particularly in fracture-dominated regions. Our analysis tests the covariability of above- and belowground features on a watershed scale, by linking borehole geophysical data...
Authors
Sebastian Uhlemann, Baptiste Dafflon, Haruko Murakami Wainwright, Kenneth Hurst Williams, Burke J. Minsley, Katrina D. Zamudio, Bradley Carr, Nicola Falco, Craig Ulrich, Susan S. Hubbard
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center

Mapped predictions of manganese and arsenic in an alluvial aquifer using boosted regression trees Mapped predictions of manganese and arsenic in an alluvial aquifer using boosted regression trees

Manganese (Mn) concentrations and the probability of arsenic (As) exceeding the drinking-water standard of 10 μg/L were predicted in the Mississippi River Valley alluvial aquifer (MRVA) using boosted regression trees (BRT). BRT, a type of ensemble-tree machine-learning model, were created using predictor variables that affect Mn and As distribution in groundwater. These variables...
Authors
Katherine J. Knierim, James A. Kingsbury, Kenneth Belitz, Paul E. Stackelberg, Burke J. Minsley, James R. Rigby
By
Water Resources Mission Area, New England Water Science Center, Lower Mississippi-Gulf Water Science Center, Geology, Geophysics, and Geochemistry Science Center

Characterizing methane emission hotspots from thawing permafrost Characterizing methane emission hotspots from thawing permafrost

Methane (CH4) emissions from climate-sensitive ecosystems within the northern permafrost region represent a potentially large but highly uncertain source, with current estimates spanning a factor of seven (11–75 Tg CH4 yr−1). Accelerating permafrost thaw threatens significant increases in pan-Arctic CH4 emissions, amplifying the permafrost carbon feedback. We used airborne imaging...
Authors
Clayton D. Elder, David R. Thompson, Andrew K Thorpe, Hrishikesh Chandanpurkar, Philip J Hanke, Nicholas Hasson, Stephanie R. James, Burke J. Minsley, Neal J. Pastick, David Olefeldt, Katey M Walter Anthony, Charles E. Miller
By
Earth Resources Observation and Science (EROS) Center , Geology, Geophysics, and Geochemistry Science Center

Permafrost characterization and feature identification using public domain airborne electromagnetic data, interior Alaska Permafrost characterization and feature identification using public domain airborne electromagnetic data, interior Alaska

The Alaska Division of Geological & Geophysical Surveys (DGGS) airborne electromagnetic (AEM) data are an excellent resource for permafrost characterization. AEM data can be used for pingo identification, estimating permafrost thickness, estimating surface talik thickness, evaluating permafrost health (temperature), talik identification and more. Data examples are shown from...
Authors
Abraham M. Emond, Ronald Daanen, Burke J. Minsley
By
Geology, Geophysics, and Geochemistry Science Center

Non-USGS Publications**

Minsley, B., D. Coles, Y. Vichabian, and F.D. Morgan (2008), Minimization of self-potential survey mis-ties acquired with multiple reference locations, Geophysics, 73(2), F71-F81, doi:10.1190/1.2829390.
Minsley, B. (2007), Modeling and inversion of self-potential data, Ph.D. Thesis, Massachusetts Institute of Technology, Cambridge, Massachusetts, 251 p.
Ajo-Franklin, J.B., B.J. Minsley, and T.M. Daley (2007), Applying compactness constraints to seismic traveltime tomography, Geophysics, 72(4), R67-R75, doi:10.1190/1.2742496.
Minsley, B., J. Sogade, and F.D. Morgan (2007), 3D source inversion of self-potential data, Journal of Geophysical Research, 112, B02202, doi:10.1029/2006JB004262.
Minsley, B., J. Sogade, and F.D. Morgan (2007), Three dimensional self potential inversion for subsurface DNAPL contaminant detection at the Savannah River Site, South Carolina, Water Resources Research, 43(4), W04429, doi:10.1029/2005WR003996.
Willis, M.E., D.R. Burns, R. Rao, B. Minsley, M.N. Toksöz, and L. Vetri (2006), Spatial orientation and distribution of reservoir fractures from scattered sesimic energy, Geophysics, 71(5), 43-51, doi:10.1190/1.2235977.

**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.

*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government

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